JP2006276526A - Image projection screen - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image projection screen which is suitable to a projector equipped with a light source such as an LED for emitting narrow wavelength band light. <P>SOLUTION: A projection unit for a rear projector includes LED light sources for emitting red narrow wavelength band light (615nm to 630nm), green narrow wavelength band light (515nm to 525nm), and blue narrow wavelength band light (460nm to 467nm). Regarding the image projection screen, a screen gain related to the blue narrow wavelength band light, a screen gain related to the green narrow wavelength band light and a screen gain related to the red narrow wavelength band light are set equal to one another, or within an extent of 10%. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an image projection screen used for a rear projector and a front projector.

  The projector, for example, separates white light emitted from an ultra-high pressure mercury lamp into red light, green light, and blue light, guides each color light to the video display panel for each color, and obtains each color obtained through each video display panel The image light is synthesized by a cross dichroic prism, and the full color image light obtained by the synthesis is projected by a projection lens (see Patent Document 1). The projected full-color image light is projected on the rear side of the image projection screen (transmission type) in the rear projector, and is projected on the front surface of the image projection screen (reflection type) in the front projector.

The transmission characteristics of a conventional image projection screen for a rear projector (a screen including a Fresnel lens and a lens) are indicated by a one-dot chain line in FIG. As can be seen from the figure, the conventional screen has a substantially flat transmittance, but the transmittance of green light is lower than that of red light, and the transmittance of blue light is lower than that of green light. Note that the characteristics of a conventional image projection screen (reflection type) for a front projector have similar reflection characteristics. Further, the gain characteristics of a conventional image projection screen for a rear projector (a screen including a Fresnel lens and a lens) are indicated by a one-dot chain line in FIG. As can be seen from this figure, the screen of the conventional screen has a lower screen gain as the wavelength becomes shorter.
JP 2005-70476 A

  By the way, when looking at the white light component emitted from the ultra-high pressure mercury lamp, the light amount of the blue light component is relatively larger than the light amount of the red light component. Further, since the amount of light cannot be adjusted for each color, there is no particular problem even if the above-described conventional video projection screen is used.

  However, in a projector that uses, for example, an LED (light emitting diode) as a light source and generates full-color video light with narrow wavelength band light that is a red component, narrow wavelength band light that is a green component, and narrow wavelength band light that is a blue component, When the image projection screen having the gain characteristic is used, the gain characteristic with respect to the blue light component is low, so that the power supplied to the LED emitting blue light must be increased, which consumes much power. Become. In general, when the screen gain is low, the viewing angle is widened, and when the screen gain is low for blue light, the image appears bluish when the screen is viewed from an oblique direction.

  In view of the above circumstances, an object of the present invention is to provide a video projection screen suitable for use in a projector including a light source such as an LED that emits light in a narrow wavelength band.

  In order to solve the above problems, the image projection screen of the present invention uses a narrow wavelength band light that is a blue light component, a narrow wavelength band light that is a green light component, and a narrow wavelength band light that is a red light component. An image projection screen that displays an image upon receiving projection of the full-color image light obtained in this way, the screen gain for the narrow wavelength band light that is the blue light component, and the narrow wavelength band light that is the green light component And the screen gain for the narrow wavelength band light, which is a red light component, are set within a range of equal to 10%.

  With the above configuration, the screen gain for the narrow wavelength band light that is the blue light component, the screen gain for the narrow wavelength band light that is the green light component, and the screen gain for the narrow wavelength band light that is the red light component, However, since it is set within a range of uniform to 10%, it is necessary to take special measures for increasing the light amount of the blue light component even when used for a projector having a light source such as an LED that emits light in a narrow wavelength band. There is no problem (e.g., avoiding an increase in power consumption), and the problem that only blue light is particularly conspicuous when the screen is viewed obliquely can be avoided.

In addition, the image projection screen according to the present invention is a full-color image obtained by using a narrow wavelength band light that is a blue light component, a narrow wavelength band light that is a green light component, and a narrow wavelength band light that is a red light component. An image projection screen that displays an image upon receiving light projection, wherein the transmittance for the narrow wavelength band light that is the blue light component is B ₁ and the transmittance for the narrow wavelength band light that is the green light component is G _1, and the transmittance to the narrow wavelength band light as the red light component When R _1, characterized in that it is set to _{R 1 ≦ G 1 ≦ B 1} .

In addition, the image projection screen according to the present invention is a full-color image obtained by using a narrow wavelength band light that is a blue light component, a narrow wavelength band light that is a green light component, and a narrow wavelength band light that is a red light component. An image projection screen that displays an image upon receiving light projection, wherein the reflectance for the narrow wavelength band light that is the blue light component is B _2, and the reflectance for the narrow wavelength band light that is the green light component is G ₂ and R ₂ is set to R ₂ ≦ G ₂ ≦ B _2, where R ₂ is a reflectance with respect to narrow wavelength band light that is a red light component.

  Even in these configurations, it is not necessary to take a special measure for increasing the light amount of the blue light component, and an increase in power consumption can be avoided.

  In the image projection screen having these configurations, the first narrow wavelength band light, the second narrow wavelength band light, and the third narrow wavelength band light may be light emitted from the solid state light emitting device. The solid state light emitting device may be a light emitting diode.

  With the image projection screen of the present invention, it is not necessary to take special measures for increasing the amount of light for the blue light component even when used in a projector equipped with a light source such as an LED that emits light in a narrow wavelength band (power consumption). In addition, there are various effects such as avoiding the problem that only blue light is particularly conspicuous when the screen is viewed obliquely.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS.

  A schematic configuration of the rear projector will be described with reference to FIGS. 3 and 4. The full-color image light emitted from the projection unit 1 is reflected by the rear mirror 2 and guided to the image projection screen 3. For example, as shown in FIG. 6, the projection unit 1 includes three illumination devices 11R, 11G, and 11B (hereinafter, the symbol “11” is used when each illumination device is not specified). The LED light source 12 of the illumination device 11R emits red light, the LED light source 12 of the illumination device 11G emits green light, and the LED light source 12 of the illumination device 11B emits blue light. In this embodiment, for example, the wavelength band of the red light is 615 nm to 630 nm, the wavelength band of the green light is 515 nm to 525 nm, and the wavelength band of the blue light is 460 nm to 467 nm.

  The light emitted from the LED light source 12 of each lighting device 11 is guided to the transmissive liquid crystal display panels 13R, 13G, and 13B for the respective colors (hereinafter, when the individual liquid crystal display panels are indicated without being specified, the reference numeral “13”). Is used). Each liquid crystal display panel 13 includes an incident-side polarizing plate, a panel portion in which liquid crystal is sealed between a pair of glass substrates (pixel electrodes and alignment films are formed), and an output-side polarizing plate. . The modulated light (each color video light) modulated by passing through the liquid crystal display panels 13R, 13G, and 13B is synthesized by the dichroic prism 14 to be full color video light. This full-color image light is enlarged and projected by the projection lens 15. The illuminating device 11 includes an LED light source 12 in which LEDs 16... Are arranged in an array, and a fly-eye lens pair 17 that integrates and guides light emitted from each LED light source 12 to the liquid crystal display panel 13. Of course, such a rear projector and the illuminating device 11 are examples, and are not limited to such a configuration.

  FIG. 1 is a diagram showing ideal characteristics of the image projection screen 3. This characteristic indicates a screen gain characteristic with respect to the wavelength of light. As described in the conventional example, the screen gain characteristic of the conventional image projection screen (transmission type) is shown by a one-dot chain line in FIG. The image projection screen 3 includes a screen gain for the blue narrow wavelength band light (460 nm to 467 nm), a screen gain for the green narrow wavelength band light (515 nm to 525 nm), and the red narrow wavelength band light (615 nm to 630 nm). ) Is set within a range of equal to 10%.

  In the case of the image projection screen 3 having such a screen gain, it is necessary to take a special measure for increasing the light amount of the blue light component even when used in a projector including the LED light source 12 that emits light in a narrow wavelength band. No (e.g. avoiding increased power consumption). Further, it is possible to avoid the problem that only blue light is particularly conspicuous when the screen is viewed obliquely. That is, it is possible to avoid the white color temperature from being lowered.

  The screen gain for the blue narrow wavelength band light, the screen gain for the green narrow wavelength band light, and the screen gain for the red narrow wavelength band light may be set within a range of equal to 10%. Even the screen gain of the intermediate wavelength band light of the wavelength band light does not need to be set within the range of equal to 10%. Further, in the screen gain characteristic shown in FIG. 1, the blue light component characteristic is improved while maintaining the screen gain characteristic with respect to the red light component, but a slight light amount reduction is allowed, that is, the red light component. The screen gain characteristics for the blue narrow wavelength band light, the screen gain for the green narrow wavelength band light, and the screen gain for the red narrow wavelength band light are set within a range of equal to 10%. It is good as well.

FIG. 2 is a diagram showing ideal characteristics of the image projection screen 3. This characteristic indicates the transmission characteristic with respect to the wavelength of light. As described in the conventional example, the transmission characteristics of the conventional image projection screen (transmission type) are indicated by a one-dot chain line in FIG. The image projection screen 3 has a transmittance for the blue narrow wavelength band light (460 nm to 467 nm) as B ₁ , a transmittance for the green narrow wavelength band light (515 nm to 525 nm) as G ₁ , and the red narrow wavelength band. When the transmittance with respect to the band light (615 nm to 630 nm) is R ₁ , R ₁ ≦ G ₁ ≦ B ₁ is set.

  With the image projection screen 3 having the above characteristics, it is not necessary to take a special measure for increasing the amount of light for the blue light component, and an increase in power consumption can be avoided.

For the reflection type (front projector) image projection screen, the reflectance for the blue narrow wavelength band light (460 nm to 467 nm) is B ₂ and the reflectance for the green narrow wavelength band light (515 nm to 525 nm) is G. ₂ and R ₂ ≦ G ₂ ≦ B _2, where R ₂ is the reflectance for the red narrow wavelength band light (615 nm to 630 nm).

In the above-described transmittance and reflectance settings, the transmittance and reflectance of the red light component in the existing characteristics are sacrificed (allowing for a reduction in the amount of light), and further, the transmittance and reflectance of the green light component. May be sacrificed (allowing for a decrease in the amount of light), and R ₁ ≦ G ₁ ≦ B ₁ or R ₂ ≦ G ₂ ≦ B ₂ may be ensured. For example, a film having no absorption for light in the wavelength band of 468 nm or less and having some absorption for light in the wavelength band exceeding 468 nm, and no absorption for light in the wavelength band of 526 nm or less and 526 nm. A film or the like having some absorbability with respect to light in the wavelength band exceeding may be attached to the screen. Further, a light absorbing material having some absorption with respect to the entire band or a part of the green narrow wavelength band light (515 nm to 525 nm) and the entire band or one band of the red narrow wavelength band light (615 nm to 630 nm). You may apply | coat etc. to the screen with the light absorption material which has some absorptivity with respect to a partial zone | band.

  Further, it is possible to perform a functional operation by controlling the directivity of localization, propagation, light emission, and light reception of an electromagnetic field in a spatial region having a structure in a multidimensional photonic crystal (Japanese Patent Application Laid-Open No. 2004-2004). 233476 and JP-A-2003-240934). Therefore, the transmittance characteristics of the image projection screen may be controlled by controlling “localization and propagation”, and the screen gain characteristics may be controlled by controlling “light emission”.

  As the image projection screen 3, a transmissive screen such as a Fresnel lens screen or a lenticular lens screen is used. A matte screen, a bead screen, or the like can be used as the reflective image projection screen. In the above description, the wavelength band of the emitted light of the LED is an exemplification, and is not limited to the numerical values shown in this embodiment. Moreover, not only LED but the other solid light emitting element (for example, electroluminescence etc.) which radiate | emits narrow wavelength band light can be used.

It is explanatory drawing which showed the example of the characteristic of the screen for image projections of this invention. It is explanatory drawing which showed the other example of the characteristic of the screen for image projections of this invention. It is explanatory drawing which showed schematic structure of the rear projector. It is explanatory drawing which showed schematic structure of the projection unit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Projection unit 3 Screen for image projection 12 LED light source

Claims (5)

An image that displays an image by receiving projection of full-color image light obtained by using a narrow wavelength band light that is a blue light component, a narrow wavelength band light that is a green light component, and a narrow wavelength band light that is a red light component A projection screen, wherein the screen gain for the narrow wavelength band light that is the blue light component, the screen gain for the narrow wavelength band light that is the green light component, and the screen gain for the narrow wavelength band light that is the red light component; Is set within a range of uniform to 10%. An image that displays an image by receiving projection of full-color image light obtained by using a narrow wavelength band light that is a blue light component, a narrow wavelength band light that is a green light component, and a narrow wavelength band light that is a red light component A projection screen, wherein the transmittance for the narrow wavelength band light that is the blue light component is B ₁ , the transmittance for the narrow wavelength band light that is the green light component is G _1, and the narrow wavelength band that is the red light component An image projection screen characterized in that R ₁ ≦ G ₁ ≦ B _1, where R ₁ is the transmittance for light. An image that displays an image by receiving projection of full-color image light obtained by using a narrow wavelength band light that is a blue light component, a narrow wavelength band light that is a green light component, and a narrow wavelength band light that is a red light component A projection screen, wherein the reflectance for the narrow wavelength band light that is the blue light component is B ₂ , the reflectance for the narrow wavelength band light that is the green light component is G _2, and the narrow wavelength band that is the red light component An image projection screen, wherein R ₂ ≦ G ₂ ≦ B ₂ is set, where R ₂ is a reflectance with respect to light. 4. The image projection screen according to claim 1, wherein the narrow wavelength band light that is a blue light component, the narrow wavelength band light that is a green light component, and the narrow wavelength band light that is a red light component are solid. An image projection screen characterized by being emitted from a light emitting element. 5. The image projection screen according to claim 4, wherein the solid-state light emitting element is a light emitting diode.

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